Cardiac signal vector selection with monophasic and biphasic shape consideration

The claimed invention is: 1. An implantable cardiac device comprising: a plurality of electrodes configured for sensing electrical signals; and operational circuitry configured for analyzing signals received from the sensing electrodes, wherein the operational circuitry and electrodes are configured to define at least two sensing vectors for sensing cardiac signals and the operational circuitry is configured to perform the following: for a first sensing vector, calculating each of: an estimate of signal-to-noise ratio; an estimate of cardiac signal amplitude; and a measure of biphasic or monophasic nature of sensed signals; and combining the signal to noise ratio, cardiac signal amplitude and measure of biphasic or monophasic nature of sensed signals to generate a sensing quality metric for the first sensing vector; wherein: the operational circuitry is further configured to sense a plurality of cardiac cycles with selected electrodes for the first vector by applying a detection profile to a sensed cardiac signal to detect a cardiac cycle, wherein the detection profile includes a refractory period and a sensing period, the refractory period being applied to a first portion of the cardiac cycle and the sensing period being applied to at least a second portion of the cardiac cycle; and the operational circuitry is configured to calculate a measure of biphasic or monophasic nature of cardiac cycles by comparing an average sensed positive amplitude from the first portion of two or more of the cardiac cycles to an average sensed negative amplitude from the first portion of two or more of the cardiac cycles. 2. An implantable cardiac device comprising: a plurality of electrodes configured for sensing electrical signals; and operational circuitry configured for analyzing signals received from the sensing electrodes, wherein the operational circuitry and electrodes are configured to define at least two sensing vectors for sensing cardiac signals and the operational circuitry is configured to perform the following: for a first sensing vector, calculating each of: an estimate of signal-to-noise ratio; an estimate of cardiac signal amplitude; and a measure of biphasic or monophasic nature of sensed signals; and combining the signal to noise ratio, cardiac signal amplitude and measure of biphasic or monophasic nature of sensed signals to generate a sensing quality metric for the first sensing vector; wherein: the operational circuitry is configured to combine the signal to noise ratio, cardiac signal amplitude and measure of biphasic or monophasic nature of cardiac signals to generate a sensing quality metric for the first sensing vector comprises the operational circuitry by finding the sum or product of: a first metric related to the signal to noise ratio; a second metric related to the cardiac signal amplitude; and a third metric related to the measure of biphasic or monophasic nature of cardiac signals. 3. An implantable cardiac device comprising: a plurality of electrodes configured for sensing electrical signals while implanted; and operational circuitry configured for analyzing signals received from the sensing electrodes, wherein the operational circuitry and electrodes are configured to define at least two sensing vectors for sensing cardiac signals and the operational circuitry is configured to perform the following: for a first sensing vector, calculating each of: an estimate of signal-to-noise ratio; an estimate of cardiac signal amplitude; and a measure of biphasic or monophasic nature of sensed signals; and combining the signal to noise ratio, cardiac signal amplitude and measure of biphasic or monophasic nature of sensed signals to generate a sensing quality metric for the first sensing vector; wherein: the operational circuitry is configured to combine the signal to noise ratio, cardiac signal amplitude and measure of biphasic or monophasic nature of cardiac signals to generate a sensing quality metric for the first sensing vector comprises the operational circuitry by calculating a sensing vector score for the first vector using the signal to noise ratio and the cardiac signal amplitude, and adjusting the score in view of the measure of biphasic or monophasic nature of cardiac signals. 4. The implantable cardiac device of claim 1 wherein the operational circuitry is further configured to perform the following: for a second sensing vector, the operational circuitry calculating each of: an estimate of signal-to-noise ratio; an estimate of cardiac signal amplitude; and a measure of biphasic or monophasic nature of sensed signals; and combining the signal to noise ratio, cardiac signal amplitude and measure of biphasic or monophasic nature of sensed signals to generate a sensing quality metric for the second sensing vector; and using the sensing quality metrics for the first and second sensing vectors to select from at least the first and second sensing vectors a sensing vector for use in cardiac signal analysis. 5. The implantable cardiac device of claim 1 wherein the operational circuitry is further configured to select a default sensing vector for use in the analysis of cardiac signals using at least one factor related to the measure of biphasic or monophasic nature of cardiac signals generated for the first sensing vector. 6. The implantable cardiac device of claim 1 , wherein, in order to establish a measure of biphasic or monophasic nature of cardiac signals, the operational circuitry performs the following: identifying a QRS portion of a cardiac cycle; and comparing a positive peak in the QRS portion of the cardiac cycle to a negative peak in the QRS portion of the cardiac cycle. 7. The implantable cardiac device of claim 1 wherein, in order to establish a measure of biphasic or monophasic nature of cardiac signals, the operational circuitry performs the following: detecting an event in a signal sensed along the first sensing vector; defining a window associated with the detected event; and comparing a positive peak in the window to a negative peak in the window. 8. The implantable cardiac device of claim 1 wherein the operational circuitry is further configured to calculate the estimate of cardiac signal amplitude by analyzing a sensed amplitude from the first portion of the cardiac cycle for each of two or more cardiac cycles. 9. The implantable cardiac device of claim 1 wherein the operational circuitry is further configured to calculate an estimate of signal to noise ratio by comparing a sensed amplitude from the first portion of the cardiac cycle to a sensed amplitude from the second portion of the cardiac cycle for each of two or more cardiac cycles. 10. The implantable cardiac device of claim 2 wherein the operational circuitry is further configured to perform the following: for a second sensing vector, the operational circuitry calculating each of: an estimate of signal-to-noise ratio; an estimate of cardiac signal amplitude; and a measure of biphasic or monophasic nature of sensed signals; and combining the signal to noise ratio, cardiac signal amplitude and measure of biphasic or monophasic nature of sensed signals to generate a sensing quality metric for the second sensing vector; and using the sensing quality metrics for the first and second sensing vectors to select from at least the first and second sensing vectors a sensing vector for use in cardiac signal analysis. 11. The implantable cardiac device of claim 2 wherein the operational circuitry is further configured to select a default sensing vector for use in the analysis of cardiac signals using at least one factor related to the measure